SE515498C2 - Device for communication systems - Google Patents

Abstract

A telecommunications system, for instance HIPERLAN, operates with asynchronous as well as synchronous communication and with an access function. The access function secures access guarantee to the communications medium for respective synchronous function after connection. The access system raises the spectrum efficiency, the capacity and the efficiency in the system. The access function also guarantees that the first type of nodes get a wanted predetermined bandwidth. <IMAGE>

Description

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a simplified view of the access method EY-NPMA.

Fig. 2 is a view of the previous invention ISAK.

Fig. 3 shows the minimum time Tlm (Least time between nodes) with which it is possible to reserve two successive packets (BRP + TP) with ISAK.

Fig. 4 shows how DRS to increase spectrum efficiency strives to place mod 2 reservations next to each other to increase spectrum efficiency.

In one embodiment, the HIPERLAN will consist of two modes, one of which is specified. The specified mode (mode l) is intended for asynchronous communication and large packets. The second mode (mode 2) must be adapted for synchronous communication such as voice, video and be able to carry ATM packets of service class types A and B efficiently.

ATM service class A corresponds to connection-oriented traffic with a constant bit rate and where there is a synchronization dependence between the endpoints.

Examples of such traffic are 64 kbps voice channels and circuit-switched 2 Mbps ATM service class B represents connection-oriented traffic with a synchronization dependency and which supports variable bit rate. Variable bit rate speech and video encoders are examples of service class B.

However, ATM packets are small compared to normal LAN packets. this entails certain problems as both moderns must nevertheless be able to effectively share the same channels.

Mode 1 can in one embodiment use an access method called EY-NPMA (Elimination Yield Nonpreemptive Priority Multiple Access). This access method contains three phases, PAP (Priority Access Phase), CP (Contention Phase) and TP (Transmission Phase), see Figure 1. l The PAP sends the emergency out priority (of five different PAP priority levels) on that packet it wants to send. The priority is set by the MAC layer with information from the overlying OSI layer.

To distinguish nodes that send packets with the same AFP priority, there is CP, in which the nodes compete for the medium. After CP, only one node remains that can send a packet in TP (a packet consists of one or fl your smaller blocks). 10 15 20 25 30 35 515 498 EY-NPMA does not guarantee access to the communication medium for more than one subsequent packet, which is required for synchronous services such as voice, video, etc. Furthermore, EY-NPMA is a very spectrum-efficient access method for small packages.

Efficiencies less than 2.20 for ATM packets (53 bytes) are to be expected. Simulations have been performed where 90% of the packets are small (64 bytes) and 10% are large 1,500 bytes). Then the net data speed in HIPERLAN will be approximately 5 Mbps from a raw data speed of 23.5 Mbps. The efficiency in this case will be just under 0.25.

Figure 2 describes the basic implementation of the ISAK access method, which is based on adding a BRP (Bandwidth Reservation Phase) after PAP and CP. BRP states, among other things, how much bandwidth mod 2 node reserves after the need has gained access to the medium.

The proposed development of DRS is thus an extension of the basic implementation of ISAK.

The device and method according to the invention increase the spectral power of ISAK.

The invention also includes a method that can be used to check that mode 2 nodes do not have the ability to reserve the entire bandwidth.

PAP + CP consists on average of about 2,000 bits (can vary from a few hundred to just over 4,000 bits). To transmit an ATM packet, the following extra bits are required in TP: LBR (470 bits), channel equalizer bits (450 bits), MAC overhead (400 bits). The total number of bits for sending an ATM packet 53 bytes (424 bits) is thus about 3,500 bits.

Figure 3 shows a problem with ISAK where if the time slot between two reservations does not hold PAP + CP + TP, no node can send information there.

The time between two subsequent TPs can in some cases (at very small values of Tlm) not be used by mod 1 nodes or new mod 2 nodes because PAP + CP + TP does not take place within the time slot Tlm. Follow it, the spectrum will be used inefficiently.

The invention DRS solves this problem.

There is a theoretical risk that mod 2 nodes reserve all available capacity so that mod 1 nodes become "outcompeted". The invention contains a device and method which enables control and limitation of mod 2 node broadband reservations.

The invention consists in that mod 2 node: 10 15 20 25 30 35 515 498 - listens in the time interval x (eg 10 ms) and registers the times TBRn (Time Between Reservations) between reservations (BRP + TP). n = 1. ... number of reservations -1. - selects the shortest TBRmin from the TBRn, (see figure 4) which is the shortest interval in which the mod 2 node packet is stored. - in its first BRP (BRP 1) includes information in the message about the time y to the next subsequent own BRP (BRP 2).

The time y is selected so that the packet is placed within the TBRm. Furthermore, the package must be placed so that the subsequent BRP + TP (BRP 2, 3, ...) is as close as possible to the previous mode 2 reservation according to figure 4. This is to be able to place BRP + TP in the best location from a capacity point of view. - places its BRP 2 (+ TP) and subsequent BRP (+ TP) with even repetition time intervals z (z separate from or equal to y) between each other eg 10 ms. The repetition intervals are specified (as described in ISAK in BRP).

- If no TBRmm is present, the node must place BRP + TP next to time slots reserved by mode 2 nodes. If there are no previous reservations, BRP 2 can be placed arbitrarily. - may not transmit its first BRP (BRP 1) (and thus reserve bandwidth) if the spectrum has been occupied by mod 2 nodes (detect BRP) 1 time units of time x. The parameter q / x (eg 0.25) should be fixed and the same for all mod 2 nodes.

With DRS, the spectrum efficiency for ISAK is significantly increased because it becomes possible to fill “gaps” in time that were not possible before. Furthermore, mode 2 nodes clump their information next to each other, which means that the spectrum efficiency is further improved because nodes have larger gaps in the time for PAP and CP.

With the proposed access method, synchronous services will be guaranteed access to the communication medium after connection. Furthermore, the spectrum efficiency, capacity, efficiency will be increased for ISAK. The method also means that mod 1 nodes can always be guaranteed a certain bandwidth. 10 515 498 5 The invention is intended for HIPERLAN and other decentralized systems for broadband short-range communication systems. Such systems can be used for LAN, LAN interconnect, public access and possibly also in broadband local area networks as a wireless connection last "100 m" to the subscriber.

There is no prior art (apart from Telia's patent application SE 9501151-6) for efficiently combining synchronous and asynchronous decentralized wireless systems.

The invention is not limited to the above examples but can be modified within the scope of the appended claims and the inventive concept.

Claims (7)

10 15 20 25 30 35 515 498 6 PATENT REQUIREMENTS 1. 1. Device in a HIPERLAN system, characterized by an access function comprising means, preferably mod 2 nodes, which: a) listens in a time interval x (eg 10 ms) after a BRP + a TP and registers times TBR "between reservations BRP + TP, where n = 1 ... number of reservations-1; b) selects the shortest TBRm from TBR", which is the shortest interval in which mod 2 node packets are accommodated in, and c) in its first BRP (BRP 1) includes information in the message about a time y to the next subsequent own BRP (BRP2). Device according to claim 1, characterized in that the time y is selected so that the packet is placed within TBRmin and that the packet is placed so that the subsequent BRP + TP (BRP 2, 3, ...) is as close as possible to the previous mode 2 reservation, which enables placement of BRP + TP in a best location from a capacity point of view. Device according to claim 2, characterized in that said means places its BRP 2 and subsequent BRP with regular repetition time intervals z between each other, e.g. 10 ms, with repetition intervals specified in BRP. Device according to one of Claims 2 or 3, characterized in that if no TBRmin is present, the node must place BRP + TP next to time slots reserved by mode 2 nodes, and that if no previous reservations exist, BRP 2 can be placed arbitrarily. Device according to one of Claims 2 to 4, characterized in that BRP is not transmitted if the spectrum has been occupied by mode 2 nodes q time units of time x, wherein the parameter q / x should be fixed and the same for all mode 2 nodes . Method in a HIPERLAN system, characterized by an access function comprising means, preferably mode 2 nodes, which: a) listens in a time interval x (eg 10 ms) after a BRP + a TP and records times TBR "Between reservations BRP + TP, where n = 1 ... number of reservations-1; 515 498 7 b) selects the shortest TBRmin from TBR ', which is the shortest interval in which mod 2 node packets are accommodated, and c) in its first BRP (BRP 1) includes information in the message of a time 5 y to the next own BRP (BRP2). Method according to claim 6, characterized in that the spectrum efficiency is increased by assigning nodes larger gaps in time for PAP and CP. 10